Intrastriatal convection-enhanced delivery results in widespread perivascular distribution in a pre-clinical model

One of the major obstacles to the effective treatment of neurological disorders ranging from brain tumours to neurodegenerative diseases is the blood-brain barrier (BBB), which regulates the passage of molecules from the circulation into the central nervous system. Increasing the dose of systemically administered therapeutics has the potential to increase intracerebral drug delivery. However, in the case of drugs such as chemotherapies, this strategy risks increased systemic side-effects which cannot be tolerated by patients. Consequently, there has been considerable neurosurgical interest in developing methods of direct interstitial drug delivery to the brain in order to bypass the BBB.

Traditionally, intracerebral drug injection techniques rely on diffusion of the therapeutic agent from the site of introduction, significantly limiting the volume of distribution [1]. Furthermore, the clinical utility of intracerebral drug injection may be hampered by tissue damage associated with insertion of cannulae for drug delivery [2]. Convection-enhanced delivery (CED) has emerged as an alternative strategy for intracerebral drug delivery using intraparenchymal microcatheters and has shown significant potential in clinical trials [3, 4]. By establishing a pressure gradient at the tip of a very fine catheter, drugs can be delivered in uniform concentration through a much larger volume of interstitial fluid. CED confers several potential advantages over conventional intracerebral injection methods, including the distribution of therapeutic agents throughout large and clinically-relevant brain volumes and avoidance of excess tissue damage. Since the concept of pressure-mediated interstitial drug delivery was first described in 1994 by Bobo et al. [5], pre-clinical researchers have focused on maximising the volume of drug distribution. It is now clear that the ability to achieve widespread, predictable and reproducible CED without reflux of infusate, is fundamentally reliant on a range of factors including catheter design, and the physicochemical properties and tissue affinity of the infused agent [2, 6‐8].

In 2005 Krauze et al. [9] reported that CED of liposomes into the putamen of non-human primates caused the liposomes to be distributed within perivascular spaces along branches of the lateral striate and middle cerebral arteries. The authors suggested that the perivascular pathways of the brain might serve as a conduit not only for endogenous molecules (as had been proposed by Szentistvanyi, Weller and others), but also interstitially infused agents [10‐12]. A number of studies have demonstrated that tracers injected into the brain parenchyma drain along perivascular spaces in grey matter and the subarachnoid space [11, 13, 14]. The unidirectional nature and rapidity of solute transport appeared to be driven by arterial pulsations, and perivascular distribution of solutes has been shown to be absent following cardiac arrest [15]. Furthermore the interstitial distribution of therapeutic molecules delivered by CED is significantly restricted by hypotension, consistent with a "perivascular pump" driven by arterial pulsations [16]. Mathematical modelling suggests that the effective perivascular elimination of soluble metabolites and waste products from the brain is fundamentally reliant on the expansile nature of the arterial wall [17, 18]. Consequently, the stiffening of arteries which occurs with ageing may be a contributing factor to the failure of Aβ elimination seen in cerebral amyloid angiopathy and Alzheimer's disease [19, 20].

Recent analysis of the perivascular pathways of the brain suggests that the perivascular drainage pathway for solutes is distinct from that of particulate materials. Carare et al. [15] compared the perivascular drainage of solutes with fluorescent particles injected into the corpus striatum of mice and demonstrated that whilst soluble infusates drained along perivascular basement membranes, particulate infusates expanded a potential space between the glia limitans and outer basement membranes of striatal vessels. Particulate infusates were ingested by resident perivascular macrophages, which have wide ranging roles in the initiation, regulation and propagation of neuroinflammatory processes [21‐23].

A number of clinical trials of CED of soluble therapeutic agents have been reported in recent years, including chemotherapies for malignant glioma (topotecan, traberdersan, nimustine) and glial cell line-derived neurotrophic factor (GDNF) for Parkinson's disease [3, 4, 24, 25]. It has been postulated that perivascular distribution might result in the immune response seen in some patients receiving intraputaminal delivery of GDNF, as a consequence of interaction with resident perivascular immune cells [9]. The aim of this study was to determine whether the perivascular distribution of solutes (fluorescein-labelled dextrans) delivered by CED into the striatum of rats is affected by the molecular weight of the infused agent, by co-infusion of vasodilator (to reduce local vascular pulsation), alteration of infusion rates or use of a ramping regime. We also wanted to make a preliminary comparison of the distribution of solutes with that of nanoparticles after CED. The potential implications of the widespread perivascular distribution of solutes for future clinical trials are also considered.

Convection-enhanced delivery has emerged as a promising technique for direct drug delivery to the brain, bypassing the blood brain barrier and enabling distribution of therapeutic agents throughout large volumes of brain parenchyma. In this study we sought to determine whether perivascular distribution is likely to be an inevitable consequence of CED of solutes, and also to determine whether the extent of perivascular distribution is affected by the molecular weight of the solute, co-infusion of vasodilator, the rate of infusion and use of a ramping regime.

Whilst the evidence for the mechanisms which drive perivascular fluid flow in the brain remains controversial, drainage of endogenous solutes along perivascular basement membranes is thought to be a consequence of bulk flow rather than simple diffusion [28]. A number of studies involving injection of tracers into the brain have demonstrated rapid and widespread distribution throughout the perivascular spaces consistent with bulk flow [14, 29, 11]. Consequently, the molecular weight of solutes might not be expected to affect the rate of perivascular drainage. In this study, significantly more 4, 10 and 20 kDa dextran than 150 kDa dextran had been taken up by perivascular macrophages 10 min following CED. Furthermore, co-localisation of 70 and 150 kDa dextran with leptomeningeal macrophages was only visible at 3 h. It seems most likely that the smaller molecular weight dextrans are simply taken up more efficiently by the macrophages, but we cannot exclude the possibility that the difference reflects an influence of the molecular weight of the solute on the rate of perivascular spread after CED, and consequently the timing of uptake by perivascular macrophages. By 3 h there was no significant difference in the extent of perivascular macrophage uptake of solutes of any molecular weight, perhaps because bulk flow takes over as the predominant driving force behind perivascular drainage once the pressure gradient is removed.

We also sought to determine whether local vasodilatation might reduce the extent of or prevent perivascular distribution of solutes. In a study incorporating mathematical modelling of perivascular drainage, Schley et al. [17] postulated that changes in the calibre of blood vessels during each pulse cycle might alter the width of the perivascular spaces thereby providing the motive force for perivascular drainage. In this model, perivascular drainage occurs mainly during periods of vasoconstriction, as a reduction in vessel calibre acts to "open" the perivascular spaces. The authors suggested that a reduction in pulse amplitude, as occurs in ageing, slows the clearance of endogenous solutes (such as Aβ peptide, resulting in perivascular deposition and cerebral amyloid angiopathy). In this study we induced local vasodilatation by co-infusing with nimodipine. By causing prolonged smooth muscle relaxation, we sought to determine whether co-infusion of nimodipine might reduce the perivascular distribution of solutes by preventing vasoconstriction in the period immediately following CED. However, this strategy did not prevent extensive perivascular spread or reduce the amount of 10 or 150 kDa dextran taken up by perivascular macrophages 10 min or 3 h following CED.

The use of slow stepwise increases in infusion rate (ramping) has been investigated in pre-clinical studies, with the aim of increasing the volume of distribution of drugs delivered by CED and to mitigate reflux [30]. Although the exact mechanisms by which ramping promotes interstitial drug distribution over reflux are not fully understood, we can hypothesise that slow stepwise increases in infusion rate might act to mechanically increase the effective pore size of the interstitial spaces of the brain. By increasing the extracellular porosity of the brain parenchyma, ramping might act to reduce the resistance to fluid flow within the interstitial spaces. In our study, there was no difference in perivascular spread or the amount of uptake of 10 kDa dextran by perivascular macrophages when the infusion rate was varied from 1 to 2.5 μl/min, or gradually increased from 0.5 to 5 μl/min. For CED to be effectively translated to clinical trials, it will be necessary to use flow rates within this range for therapeutic agents to be distributed through clinically relevant volumes of brain tissue over a time period which is acceptable to patients [31]. In our forthcoming clinical trial of intraputaminal CED of GDNF for Parkinson's disease, we intend to use flow rates of up to 5 μl/min in order to limit the period of infusion to approximately two hours.

This study suggests that widespread perivascular distribution and interaction with perivascular macrophages is likely to be an inevitable consequence of CED of solutes irrespective of their molecular weight, co-infusion with vasodilators, and use of either slow infusion rates or ramping regimes. Convection-enhanced delivery of viral vectors has previously been shown to result in transfection of perivascular macrophages, suggesting that the interaction with perivascular macrophages seen in this study is not a property of dextrans alone [31]. The recent application of advances in nanoparticle technology to CED raises the question of whether this conclusion is applicable to particulate infusates [32]. Our preliminary studies suggest that whilst CED of 20 nm nanoparticles also results in perivascular distribution, their interaction with perivascular macrophages may differ from solutes. Further studies are needed to investigate the influence of nanoparticle size and charge in greater detail.

There is evidence from pre-clinical studies in both rats and mice that the perivascular spaces of the brain are under immune surveillance by cells of monocyte/macrophage lineage which undergo continuous turn-over [33, 34]. These perivascular immune cells have been implicated in neuroinflammatory processes related to cerebral amyloid angiopathy (CAA), Alzheimer's disease (AD) and multiple sclerosis [35‐37]. Hawkes et al. demonstrated that depletion of perivascular macrophages in a transgenic mouse model of AD resulted in elevation of vascular Aβ level [35]. For disease processes involving the perivascular pathways such as CAA and AD, convection-enhanced delivery might offer a method of directing therapeutic agents to both interstitial and perivascular spaces of the brain.

Conversely, perivascular distribution of some therapies delivered by CED might be undesirable in clinical trials for a number of reasons. Uptake of therapeutic proteins by perivascular macrophages might elicit a neutralising or damaging immune response (which may have contributed to the lack of efficacy seen in clinical trials of GDNF delivery to the putamen [9]). The perivascular drainage of drugs delivered into deep grey matter structures might also result in distribution into the subarachnoid space. In a clinical context, this could result in unwanted side-effects such as nerve root irritation. Furthermore, widespread perivascular distribution of cytotoxic chemotherapies might significantly reduce (or eliminate) the resident perivascular immune cell population, resulting in impaired handling of toxic metabolites and dampening of the innate immune response to tumour cells [35].

This study suggests that CED of soluble pharmacological agents is likely to result in perivascular distribution and interaction with perivascular macrophages, irrespective of the molecular weight of the therapeutic agent or the infusion regime used. The potential consequences of widespread perivascular distribution of therapeutic agents, and in particular cytotoxic chemotherapies, delivered by CED must be carefully considered to ensure safe and effective translation to clinical trials.